JP2002334474A - Aberration detecting method, optical recording and reproducing method using this detecting method and device therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an aberration detecting method that improves detection sensitivity of spherical aberration generating in a beam-condensing optical system. SOLUTION: A light beam passing a two-element objective lens 9, which is a beam-condensing optical system equipped in an optical pickup device 10, is emitted to the flat region of an optical disk 6, with its reflected light used for detecting the aberration that generates in the two-element objective lens 9.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an aberration detecting method for detecting an aberration occurring in a converging optical system of an optical pickup device, an optical recording / reproducing method using the aberration detecting method, and an optical recording / reproducing apparatus. is there.

[0002]

2. Description of the Related Art In recent years, there has been a demand for increasing the recording density of an optical disk with an increase in the amount of information. Higher recording densities of optical disks have been achieved by increasing the linear recording density in the information recording layer of the optical disk and by narrowing the track pitch. In order to cope with the increase in the recording density of the optical disk, it is necessary to reduce the beam diameter of the light beam focused on the information recording layer of the optical disk.

As a method of reducing the beam diameter of a light beam, a numerical aperture (NA) of a light beam emitted from an objective lens as a condensing optical system of an optical pickup device for recording and reproducing an optical disk is increased. Thus, the wavelength of the light beam can be shortened.

[0004] Shortening of the wavelength of a light beam is considered to be feasible by changing the light source from a red semiconductor laser to a blue-violet semiconductor laser that has been fully commercialized.

On the other hand, as a technique for realizing an objective lens having a high numerical aperture, a hemispherical lens is combined with the objective lens.
A method of realizing a high numerical aperture by forming an objective lens with two lenses (two-group lenses) has been proposed.

Generally, in an optical disc, the information recording layer is covered with a cover glass in order to protect the information recording layer from dust and scratches. Therefore, the light beam transmitted through the objective lens of the optical pickup device passes through the cover glass, and is condensed and focused on the information recording layer thereunder.

When a light beam passes through a cover glass, a spherical aberration (SA) occurs. The spherical aberration SA is represented by SA∝d · NA ⁴ ... (1), and the thickness d of the cover glass and the N of the objective lens
It is proportional to the fourth power of A. Usually, the objective lens is designed to cancel the spherical aberration, so that the spherical aberration of the light beam passing through the objective lens and the cover glass is sufficiently small.

However, if the thickness of the cover glass deviates from a predetermined value, a spherical aberration occurs in the light beam converged on the information recording layer, and the beam diameter becomes large. There is a problem that reading and writing cannot be performed correctly.

From the above equation (1), it can be seen that as the thickness error Δd of the cover glass increases, the error ΔSA of the spherical aberration increases and the information cannot be read and written correctly.

[0010] Further, as a multilayer optical disk formed by laminating information recording layers so that the density of recorded information can be increased in the thickness direction of the optical disk, for example, a DVD having two information recording layers ( Digital Veratile Disc) has already been commercialized. In such an optical pickup device for recording and reproducing a multilayer optical disk, it is necessary to condense a light beam sufficiently small for each information recording layer of the optical disk.

In the case of a multi-layer optical disk having the above-mentioned information recording layer, since the thickness from the surface of the optical disk (cover glass surface) to each information recording layer is different, the light beam is generated when the light beam passes through the cover glass of the optical disk. Spherical aberration varies for each information recording layer. In this case, for example, the difference (error ΔSA) in the spherical aberration generated between the adjacent information recording layers is proportional to the interlayer distance t (corresponding to d) between the adjacent information recording layers according to Expression (1).

In a DVD having two information recording layers, the NA of the objective lens of the optical pickup device is as small as about 0.6. Therefore, from the above equation (1), even if the cover glass thickness error Δd is slightly increased, It can be seen that the influence of the spherical aberration on the error ΔSA is small.

Therefore, in a conventional DVD device using an optical pickup device having a numerical aperture NA of about 0.6, the D
The error ΔSA of the spherical aberration caused by the thickness error Δd of the cover glass of the VD is small, and the light beam condensed for each information recording layer can be sufficiently small.

However, even if the thickness error Δd of the cover glass is equal, the larger the NA, the larger the spherical aberration SA.
Occurs. For example, compared to NA = 0.6, NA =
At 0.85, approximately four times the spherical aberration SA occurs. Therefore, from the above equation (1), it can be seen that the higher the NA, such as NA = 0.85, the greater the spherical aberration caused by the thickness error of the cover glass.

Similarly, in the case of a multilayer optical disk, even if the interlayer distances t between adjacent information recording layers are equal, the larger the NA of the objective lens of the optical pickup device, the larger the difference in spherical aberration (error ΔSA) occurs. For example, NA =
At NA = 0.85 compared to 0.6, an approximately four-fold difference in spherical aberration occurs. Therefore, from the above equation (1),
It can be seen that the higher the NA, such as NA = 0.85, the greater the difference in spherical aberration between each information recording layer.

Therefore, with an objective lens having a high NA, the effect of the error of the spherical aberration cannot be neglected, and a problem arises that the information reading accuracy is reduced. Therefore, it is necessary to correct spherical aberration in order to achieve high recording density using an objective lens having a high NA.

Therefore, as a method of detecting and correcting spherical aberration, for example, Japanese Patent Application Laid-Open No. 2000-171346 discloses
An optical pickup device that detects and corrects the above-mentioned spherical aberration is disclosed. In this optical pickup device, when the light beam is focused on the information recording layer of the optical disk, the focusing position of the light beam is different between the beam near the optical axis and the beam outside the vicinity of the optical axis due to spherical aberration. I use.

According to the optical pickup device disclosed in the above publication, the light beam to be detected is separated into a light beam near the optical axis of the light beam and a light beam outside the vicinity of the optical axis by an optical element such as a hologram. When aberration occurs, the shift of the condensing position of one of the light beams from the information recording layer is detected, the spherical aberration is corrected based on the detection result, and the light beam condensed for each information recording layer of the optical disc is detected. The diameter can be made sufficiently small.

[0019]

On the optical recording medium, land / grooves or pits for recording information or the like are formed. The width of these lands / grooves or pits must be smaller than the diameter of the light spot because it is necessary to surely catch the land / groove or pit by a light spot formed on the optical recording medium by light beam irradiation.

For this reason, the light beam applied to the optical recording medium becomes reflected light including diffracted light having different orders due to land / grooves or pits which become irregularities on the surface of the optical recording medium, and is provided in the optical pickup device. This returns to the objective lens that constitutes the condensing optical system. For example, FIG.
As shown in (2), the light reflected by the land / groove of the optical disc returns to the objective lens in a state where diffracted lights (0-order light, ± 1st-order light) of different orders overlap.

As described above, when the diffracted lights having different orders, that is, the reflected light in the state where the 0th-order light and the ± 1st-order light overlap each other, return to the objective lens of the condenser optical system, the light intensity of the reflected light is reduced This causes a problem of lowering the sensitivity of detecting spherical aberration generated in the condensing optical system.

Further, in order to properly record and reproduce information on and from the optical recording medium, it is necessary to detect and correct spherical aberration even during recording and reproducing of information on the optical recording medium.

However, detecting and correcting the spherical aberration during the recording and reproduction of information on the optical recording medium requires complicated control.
There is a problem that it is difficult to properly detect spherical aberration.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide an aberration detection method for improving the detection sensitivity of spherical aberration generated in a condensing optical system, and this aberration detection method. It is an object of the present invention to provide an optical recording / reproducing method and an optical recording / reproducing apparatus which can detect and correct spherical aberration by simple control even when recording / reproducing information on an optical recording medium using the method.

[0025]

In order to solve the above-mentioned problems, the aberration detecting method of the present invention uses a light beam passing through a converging optical system provided in an optical pickup device to flatten the optical recording medium. It is characterized by irradiating an area and detecting the aberration generated in the condensing optical system using the reflected light.

Generally, grooves, lands, or pits necessary for recording and reproducing information are formed on an optical recording medium, and the groove width, land width, and bit width are smaller than the spot diameter of the light beam to be irradiated. If the reflected light
Includes diffracted light (0th-order light, ± 1st-order light, etc.) of different orders generated by grooves, lands or pits. With such reflected light, the light intensity is reduced, and the sensitivity of detecting aberrations generated in the light collecting optical system is reduced. Here, the aberration mainly indicates spherical aberration.

On the other hand, the reflected light from the grooves or lands of the optical recording medium or the flat area where no pits are formed is only the 0th-order light. It is possible to improve the detection sensitivity of the aberration generated in the system.

Therefore, as in the above configuration, the detection of the aberration generated in the condensing optical system of the optical pickup device is performed by using the reflected light of the light beam from the flat area of the optical recording medium. Sensitivity can be improved.

The flat area may be a flat area existing between a reproduction area or a recording area of the optical recording medium.

In this case, in a flat area existing between the reproduction area and the recording area of the optical recording medium, the light beam is reflected while the influence of the area where the grooves, lands, or pits are formed is small. Is detected as little as possible, and as a result, aberration can be detected with high sensitivity.

The flat area may be a flat area existing at the innermost or outermost periphery of the optical recording medium.

In this case, the flat area existing at the innermost or outermost part of the optical recording medium is more likely to be a groove, a land, or a land than the flat area existing between the reproduction area and the recording area.
Alternatively, since it is formed at a position far from the pit formation region, the influence of diffracted light due to grooves, lands, or pits can be further reduced. This makes it possible to detect aberrations with higher sensitivity than in the case where reflected light from a flat area existing between a reproduction area and a recording area is used.

When a flat area existing between the reproduction area or the recording area of the optical recording medium is used as the flat area, or a flat area existing at the innermost or outermost area of the optical recording medium is used. Then, it is necessary to specify the position of the flat area used for aberration detection in advance.

Therefore, it is conceivable to specify the flat area based on the amount of reflected light of the light beam on the optical recording medium.

In this case, since the flat area of the optical recording medium is specified by the amount of reflected light, it is not necessary to specify the flat area in advance.

If the aberration detection is performed using the reflected light only when the flat area is specified by the amount of reflected light, the aberration can always be detected with high sensitivity.

According to the optical recording / reproducing method of the present invention, in order to solve the above-mentioned problems, information is recorded / reproduced on / from an optical recording medium using an optical pickup device, and the optical recording medium is provided in the optical pickup device. In an optical recording / reproducing method for irradiating the optical recording medium with a light beam having passed through a condensing optical system and detecting an aberration generated in the condensing optical system using reflected light, the recording of information on the optical recording medium is performed. During playback,
A flat portion existing in the optical recording medium is specified, the specified flat portion is irradiated with a light beam that has passed through the condensing optical system, and the aberration generated in the condensing optical system is reflected using the reflected light. It is characterized by detecting.

According to the above arrangement, the flat portion used for detecting the aberration generated in the light collecting optical system is specified, and the reflected light of the light beam from the specified flat portion is generated in the light collecting optical system. Since the aberration is detected, even when recording / reproducing information on / from the optical recording medium, the aberration generated in the condensing optical system can be easily and efficiently detected without complicated control. Can be detected.

The flat portion may be specified from a reproduction area of the optical recording medium or an area existing between the recording areas.

In this case, in the flat part specified from the reproduction area of the optical recording medium or the area existing between the recording areas,
Since the light beam is reflected in a state where the influence of the groove, land, or pit formed area is small, the aberration is detected in a state where the influence of the diffracted light is as small as possible,
As a result, aberration can be detected with high sensitivity.

The flat portion may be specified from a region existing at the innermost peripheral portion or the outermost peripheral portion of the optical recording medium.

In this case, the flat part specified from the innermost or outermost area of the optical recording medium is more grooved than the flat part specified from the reproduction area or the area between the recording areas. Since it is formed at a position far from the formation region of the groove, the land, or the pit, the influence of the diffracted light due to the groove, the land, or the pit can be further reduced. This makes it possible to detect aberrations with higher sensitivity than in the case where reflected light from a flat area existing between a reproduction area and a recording area is used.

The flat portion may be specified based on the intensity of light reflected from the optical recording medium.

In this case, an existing device such as an optical pickup device may be used to obtain the intensity of the reflected light, so that it is not necessary to provide a special mechanism for specifying the flat portion. Thus, a flat portion can be specified with a simple configuration when recording / reproducing information on an optical recording medium.

The position information of the flat portion existing on the optical recording medium may be recorded in the header area where the reproduction or recording position information of the optical recording medium is recorded.

In this case, when recording / reproducing information to / from the optical recording medium, the position information of the flat portion existing in the optical recording medium is recorded in the header area which is always read, so that A flat portion can be reliably specified at the time of recording and reproducing information.

Thus, it is possible to detect the aberration occurring in the light collecting optical system with high sensitivity when recording / reproducing information on / from the optical recording medium.

When the optical recording medium has a plurality of recording layers or reproduction layers, the detection of the aberration occurring in the light-collecting optical system may be performed for each recording layer or reproduction layer. .

In this case, for each recording layer or each reproduction layer,
Aberration detection can be performed with high sensitivity. Therefore, for example, even when an optical recording medium having a plurality of recording layers or reproduction layers, such as a DVD-RAM or a DVD-ROM, is used, aberration detection can be performed with high sensitivity.

In order to solve the above-mentioned problems, an optical recording / reproducing apparatus of the present invention comprises: an optical pickup apparatus for optically recording / reproducing information on / from an optical recording medium; and an optical pickup provided in the optical pickup apparatus. The light beam that has passed through the optical optics is
There are aberration detecting means for irradiating the optical recording medium and detecting the aberration generated in the condensing optical system using the reflected light, and flat part specifying means for specifying a flat part existing in the optical recording medium. The aberration detecting means detects the aberration based on the reflected light from the flat part specified by the flat part specifying means.

According to the above arrangement, when recording / reproducing information on / from the optical recording medium, the aberration detecting means reflects the reflected light from the flat part existing on the optical recording medium, which is specified by the flat part specifying means. Due to the reflected light, which is less affected by diffracted light,
Aberration detection can be performed with high sensitivity.

The flat portion specifying means may specify a flat portion from a reproduction region of an optical recording medium or a region existing between recording regions.

In this case, in the flat part specified from the reproduction area of the optical recording medium or the area existing between the recording areas,
Since the light beam is reflected in a state where the influence of the groove, land, or pit formed area is small, the aberration is detected in a state where the influence of the diffracted light is as small as possible,
As a result, aberration can be detected with high sensitivity.

The flat portion specifying means may specify a flat portion from a region existing at the innermost peripheral portion or the outermost peripheral portion of the optical recording medium.

In this case, the flat portion specified from the innermost peripheral portion or the outermost peripheral portion of the optical recording medium is larger than the flat portion specified from the reproduction region or the region existing between the recording regions.
Since it is formed at a position far from the groove, land, or pit formation region, the influence of diffracted light due to the groove, land, or pit can be further reduced. This makes it possible to detect aberrations with higher sensitivity than in the case where reflected light from a flat area existing between a reproduction area and a recording area is used.

The flat portion specifying means may specify the flat portion based on the intensity of light reflected from the optical recording medium.

In this case, the flat portion can be specified at the time of recording / reproducing information on the optical recording medium without providing a special mechanism for specifying the flat portion.

[0058]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below. In the present embodiment, an aberration detection method for detecting spherical aberration occurring in a condensing optical system constituting an optical pickup device and an optical recording / reproducing method using the same are described in an optical recording / reproducing method including the optical pickup device. An example applied to an apparatus will be described.

As shown in FIG. 1, an optical recording / reproducing apparatus according to the present embodiment includes a spindle motor 62 for rotatingly driving an optical disc 6 as an optical recording medium, an optical pickup apparatus 10 for recording / reproducing information on / from the optical disc 6, A drive control unit 51 for controlling the drive of the spindle motor 62 and the optical pickup device 10 is provided.

The optical pickup device 10 includes a semiconductor laser 1 as a light source for irradiating the optical disk 6 with a light beam, a hologram 2, a collimating lens 3, a two-element objective lens 9 as a condensing optical system, and a detecting device 7, Eight.

A mirror 63 for refracting the optical path of the light beam from the two-element objective lens 9 or the light beam from the collimator lens 3 by about 90 ° is provided between the two-element objective lens 9 and the collimator lens 3. Have been.

Further, the two-element objective lens 9 has a structure in which the first lens element 4 and the second lens element 5 are arranged in this order from the side irradiated with the light beam from the semiconductor laser 1.

The first lens element 4 is held by a holder 52 at the periphery. A focus actuator 53 and a tracking actuator 64 are provided on the outer periphery of the holder 52.

The focus actuator 53 moves the two-element objective lens 9 to an appropriate position in the direction of the optical axis to perform focusing control. Further, the tracking control is performed by moving the two-element objective lens 9 in the radial direction (the direction orthogonal to the direction of the track formed on the optical disc 6 and the direction of the optical axis) by the tracking actuator 64.

The above-described tracking actuator 64
By accurately controlling the driving of the optical disk, the optical beam
The information track is tracked accurately.

The second lens element 5 is held by a holder 54 at the periphery. A second element actuator 55 for moving the second lens element 5 in the optical axis direction is provided on the inner peripheral surface of the holder 52 facing the outer peripheral portion of the holder 54. By controlling the drive of the second element actuator 55, the distance between the first lens element 4 and the second lens element 5 is adjusted, and the optical pickup device 1 is controlled.
The spherical aberration generated in the 0 focusing optical system is corrected.

The drive control section 51 includes a spindle motor drive circuit 5 for controlling the drive of the spindle motor 62.
6. A focus drive circuit 57 for controlling the drive of the focus actuator 53, a tracking drive circuit 61 for controlling the drive of the tracking actuator 64, and a second element drive circuit 58 for controlling the drive of the second element actuator 55. A control signal generating circuit 59 for generating a control signal to each of the control circuits from the signals obtained from the detection devices 7 and 8; It has an information reproducing circuit 60 for reproducing recorded information and generating a reproduced signal.

The control signal generation circuit 59 calculates the tracking error signal TES, the focus error signal FES, and the spherical aberration signal S based on the signals obtained from the detection devices 7 and 8.
AES is generated, the tracking error signal TES is output to the tracking drive circuit 61, the focus error signal FES is output to the focus drive circuit 57, and the spherical aberration signal SAES is output to the second element drive circuit 58. In each drive circuit, drive control of each member is performed based on each error signal.

For example, when the focus error signal FES is input to the focus drive circuit 57, the two-element objective lens 9 is moved in the optical axis direction based on the value of the FES, and the focus of the two-element objective lens 9 is adjusted. The drive of the focus actuator 53 is controlled so as to correct the displacement.

When the spherical aberration signal SAES is input to the second element driving circuit 58, the second lens element 5 is moved in the optical axis direction based on the value of the SAES, and the optical pickup device 10 The driving of the second element actuator 55 is controlled so as to correct the spherical aberration generated in the optical system. However, when the spherical aberration is corrected by the spherical aberration correcting mechanism, the distance between the first lens element 4 and the second lens element 5 of the two-element objective lens 9 is fixed, and the spherical surface input to the spherical aberration correcting mechanism is fixed. The spherical aberration is corrected according to the value of the aberration signal SAES.

The details of the optical pickup device 10 will be described below with reference to FIG. In addition,
For convenience of explanation, in the optical pickup device 10 shown in FIG. 2, the mirror 63 shown in FIG. 1 is omitted.

In the optical pickup device 10, the hologram 2, the collimating lens 3, the first lens element 4 and the second lens element 5 constituting the two-element objective lens 9 are composed of the light beam irradiation surface of the semiconductor laser 1 and the light of the optical disk. The detectors 7 and 8 are disposed on the optical axis OZ formed between the beam and the beam reflecting surface, and the detectors 7 and 8 are disposed at the focal position of the diffracted light of the hologram 2.

That is, in the optical pickup device 10 having the above-described structure, the light beam emitted from the semiconductor laser 1 passes through the hologram 2 as the 0th-order diffracted light, and is converted into parallel light by the collimating lens 3. 2 composed of a first lens element 4 and a second lens element 5
The light passes through the element objective lens 9 and is focused on the information recording layer 6c or 6d on the optical disk 6.

On the other hand, the light beam reflected from the information recording layer 6c or 6d of the optical disc 6
The light passes through each member in the order of the lens second element 5, the first lens element 4, and the collimating lens 3, enters the hologram 2, is diffracted by the hologram 2, and is condensed on the detection devices 7 and 8.

The detecting device 7 includes a first light receiving portion 7a, a second
The detecting device 8 includes a third light receiving portion 8a and a fourth light receiving portion 8b. The condensed light beam is converted into an electric signal by the detecting devices 7 and 8.

The optical disk 6 has a cover glass 6a,
It comprises a substrate 6b and two information recording layers 6c and 6d formed between the cover glass 6a and the substrate 6b. That is, the optical disc 6 is a two-layer disc,
The optical pickup device 10 has an information recording layer 6c or 6d.
The information beam is condensed to reproduce information from each information recording layer and record information on each information recording layer.

Therefore, in the following description, the information recording layer of the optical disk 6 represents either the information recording layer 6c or 6d, and the optical pickup device 10 focuses a light beam on either information recording layer and Can be recorded or reproduced.

The hologram 2 has four regions 2a, 2a
b, 2c and 2d.

The first area 2a is composed of a first straight line CL1 orthogonal to the optical axis OZ and a first circle E1 centered on the optical axis OZ.
And a region surrounded by the second arc E2.

The second area 2b is defined by the first straight line CL1.
And a region surrounded by the second arc E2.

The third region 2c and the fourth region 2d are
A region of the first circle E1 opposite to the surface on which the first region 2a and the second region 2b are formed is a second straight line CL2 orthogonal to the optical axis OZ and orthogonal to the first straight line CL1. Is an area divided by.

The hologram 2 transmits the light emitted from the semiconductor laser 1 as the 0th-order diffracted light to the optical disk 6, diffracts the reflected light from the optical disk 6, and guides the light to the detection devices 7 and 8. I have.

The hologram 2 is formed so that a light beam passing through the hologram 2 from the optical disk 6 is diffracted and condensed at different points in each region.

That is, of the light beam reflected by the recorded information image on the optical disk 6, the first area 2 of the hologram 2
The first light beam diffracted by the hologram 2 forms a condensed spot at the first light receiving portion 7a of the detection device 7, and the second light beam
The second light beam diffracted in the area 2b of the
The second light receiving portion 7b forms a condensed spot, and the third light beam diffracted in the third region 2c of the hologram 2 forms a converged spot at the third light receiving portion 8a of the detection device 8, The fourth light beam diffracted by the fourth region 2d of the hologram 2 forms a converged spot at the fourth light receiving portion 8b of the eighth detector.

Here, details of the detection devices 7 and 8 will be described below with reference to FIG.

As shown in FIG. 3, the detecting device 7 is formed by juxtaposing the above two light receiving portions (first light receiving portion 7a and second light receiving portion 7b). The light receiving portions (the third light receiving portion 8a and the fourth light receiving portion 8b) are formed side by side.

The first light receiving section 7a and the second light receiving section 7b are respectively divided into two divided photodetectors 11a, 11b and 12a,
2b. Each of the light receiving units is arranged so that a converging spot of the first and second light beams is formed on a dividing line of each photodetector, and converts the light beams into electric signals.

The third light receiving section 8a and the fourth light receiving section 8b have photodetectors 13 and 14, respectively, and convert the third and fourth light beams into electric signals.

The electric signal obtained by each of the above photodetectors is
The drive controller 51 (FIG. 1) is used for the displacement of the focal position of the two-element objective lens 9 and for reproducing information from the optical disc 6.
For example, the electric signal is output to the information reproducing circuit 60 (FIG. 1) and is converted into a reproduced signal RF. At this time, the reproduction signal RF recorded on the optical disk 6 is given by the sum of the electric signals output from each photodetector.

In the optical recording / reproducing apparatus having the above-described configuration, tracking drive control is performed in order to converge the light beam emitted from the two-element objective lens 9 on a track formed on the optical disk. That is, the tracking actuator 64 (FIG. 1) is driven to move the two-element objective lens 9 in the radial direction (radial direction) of the optical disk 6 so that the light beam is focused on the track.

Here, a tracking shift (tracking error) signal TES indicating the amount of shift of the condensed beam in the radial direction from the track is obtained by the light detector 13 and the fourth light receiver of the third light receiver 8a of the detector 8. TES = 13S−14S (2) using electric signals 13S and 14S respectively output from the photodetector 14 of FIG.

The method of measuring the tracking error by obtaining the tracking error signal TES by the above equation (2) is based on the phenomenon that the reflected diffracted light pattern is unbalanced in the radial direction due to the positional relationship between the track and the condensed spot. This is called a push-pull method. Therefore, in order to measure the amount of imbalance, it is desirable that the second straight line CL2 that divides the third region 2c and the fourth region 2d of the hologram 2 be orthogonal to the radial direction.

Using the electric signal from each photodetector, two
The defocus correction of the element objective lens 9 is performed as follows.

If the focal point does not coincide with the information recording layer, the first light receiving portion 7a and the second light receiving portion 7b of the detecting device 7
Each light beam received depends on one of the photodetectors.

Therefore, the photodetectors 11a and 11a that convert the diffracted light from the first area 2a of the hologram 2 into an electric signal
Assuming that the electric signals from b are 11aS and 11bS, the first focus error signal F1 is given by F1 = 11aS−11bS (3), and the second area of the hologram 2 is obtained. The electric signals from the photodetectors 12a and 12b that convert the diffracted light from the light detector 2b into electric signals are referred to as 12aS and 12bS, and the second focus error signal F
2 is given by F2 = 12aS−12bS (4), and when the information recording layer is out of focus, the focus error signals of F1 and F2 are obtained. The output value corresponds to the amount of the focal position shift.

Therefore, in order to always keep the focal position coincident with the information recording layer, the two-element objective lens 9 is set so that the outputs of the first focus error signals F1 and F2 always become 0.
What is necessary is just to move in Z direction.

The method of detecting the defocus by the method as described above is generally called a knife edge method. Here, the focal position deviation indicates the amount of separation between the focal point where the light beam passing through the two-element objective lens 9 from the semiconductor laser 1 side is converged and the position of the information recording layer of the optical disk 6.

In the present invention, the method of detecting the defocus is not limited to the knife edge method.
For example, it is possible to use a beam size method for detecting a focus position shift from a change in beam size before and after the focus position. In this embodiment, a method for detecting a focus position shift using the knife edge method will be described.

Normally, the detection of the focus position shift signal FES is performed using the entire effective diameter of the light beam. Therefore, in the present embodiment, the formula for generating the FES is obtained by using the focus error signals F1 and F2. , FES = F1 + F2 (5)

Next, detection of spherical aberration generated in the above-mentioned condensing optical system will be described.

In the above-mentioned condensing optical system, spherical aberration occurs due to a change in the thickness of the cover glass 6a of the optical disk 6. When the spherical aberration occurs, an offset occurs in the focal position shift signal FES. Therefore, even if the detected focal position shift signal FES outputs 0, the light beam does not coincide with the best image point on the information recording layer, and May not be able to be recorded and reproduced.

When spherical aberration occurs, the focal position differs between the inner and outer peripheral portions of the light beam. Therefore, by detecting the defocus between the inner and outer peripheral portions of the light beam,
Spherical aberration generated in the condensing optical system can be detected. In the present embodiment, since the first focus error signal F1 and the second focus error signal F2 detect the defocus of the inner and outer peripheral portions of the light beam, respectively, the generation equation of the spherical aberration signal SAES is: SAES = F1 (6) or SAES = F2 (7) and the first focus error The signal F1 or the second focus error signal F
2 can be detected from either one of the signals.

However, when spherical aberration and defocus occur, the first focus error signal F1 or the second focus error signal F2 indicating the spherical aberration signal changes due to the defocus, and the spherical aberration cannot be detected accurately.

Therefore, it is necessary to detect the spherical aberration while minimizing the effect of defocus. To suppress the effect of defocus, the spherical aberration signal SAES is calculated by the following equation: SAES = F1− (F1 + F2) × K1 (K1 is a coefficient (8) Alternatively, SAES = F2− (F1 + F2) × K2 (K2 is a coefficient) (9) At this time, the constants K1 and K2 are determined so that the change in SAES becomes small even if a defocus occurs.

In this embodiment, the spherical aberration is detected by using the knife edge method. However, the spherical aberration can be detected by using, for example, the beam size method. Further, in order to detect spherical aberration with the highest sensitivity, the second arc E2 of the hologram 2 dividing the inner peripheral portion and the outer peripheral portion of the light beam.
Is preferably set to approximately 70% of the effective diameter of the objective lens.

The spherical aberration is detected by the above method, and the spherical aberration is corrected so that the spherical aberration is reduced.

Generally, although not shown, grooves, lands, or pits necessary for recording and reproducing information are formed on the optical disk 6, and the groove width, land width, and bit width are determined by the spot of the light beam to be irradiated. It is formed smaller than the diameter.

Therefore, as shown in FIG. 6, the reflected light of the light beam irradiated on the optical disk 6 and reflected by the information recording layer 6c or 6d has diffracted light of different orders (0th order) generated by grooves, lands or pits. Light and ± 1
Secondary light, etc.). When such reflected light overlaps and returns to the objective lens (the two-element objective lens 9), when spherical aberration occurs, a change in the diffracted light pattern occurs at a portion where the 0th-order light and ± 1st-order light overlap each other. The intensity distribution is no longer uniform.

For this reason, the intensity changes at the light beam inner peripheral portion and the light beam outer peripheral portion, and in the above case where the spherical aberration is detected using the light beam at the light beam inner peripheral portion or the outer peripheral portion, the accurate Cannot perform spherical aberration detection. As described above, the sensitivity of the spherical aberration signal is deteriorated due to the influence of the diffracted light.

Therefore, the spherical aberration can be detected with high sensitivity if the influence of the diffracted light generated by the reflection of the light beam on the information recording layer of the optical disk 6 is minimized. In order to reduce the influence of the diffracted light, the spherical aberration may be detected by the light beam reflected on the flat area of the optical disk 6 where the diffracted light is less generated.

Here, the spherical aberration signal and the cover glass 6a of the optical disk 6 when the light beam is reflected by the flat region (flat portion) of the optical disk 6 and when the light beam is reflected by the land / groove of the optical disk 6 FIG. 4 shows the relationship with the thickness error.

From the graph shown in FIG. 4, it is apparent that the sensitivity of the spherical aberration signal SAES when reflected by the flat portion is higher than that of the spherical aberration signal SAES.
Spherical aberration signal SAE when reflected by land / groove
It can be seen that the sensitivity of S has decreased. In other words, it can be seen that the sensitivity of the spherical aberration signal SAES detected in a state where the light is reflected and greatly affected by the diffracted light, such as a land or groove, is reduced.

As described above, the spherical aberration can be detected with high sensitivity from the light beam reflected by the flat portion.

Therefore, the flat portion for detecting spherical aberration may be set at an arbitrary position on the optical disc 6 in advance, or an existing flat area on the optical disc 6 may be used. For example, DVD
A mirror area between recording areas as shown in FIG. 5, a land area at the innermost and outermost areas, such as a RAM,
A region having no groove or pit may be used as a flat portion of spherical aberration. If the spherical aberration is detected while the light beam is being reflected in the mirror area, the land, the groove, or the pit-free area, the spherical aberration can be detected with high sensitivity.

In the case of a DVD-ROM, even if there are pits, a state where no pit is present in the track from which information is reproduced continues. A region with a similar state is created.
These regions may be used as flat portions for detecting spherical aberration.

As described above, in order to detect spherical aberration from the light beam reflected on the flat portion of the optical disc 6, it is necessary to know that the light beam is reflected on the flat portion of the optical disc 6.

As a method of knowing that the light beam is reflected on the flat portion of the optical disk 6, for example, information for specifying the position of the flat portion may be recorded on the optical disk 6 in advance. For example, it is conceivable to record information for specifying the position of a flat portion used for spherical aberration detection in a header portion of an area of the optical disc 6 where information is recorded. In this case, it is possible to know when the light beam is reflected on the flat portion only by reading the header portion.

As another method for knowing that the light beam is reflected by the flat portion of the optical disk 6, the optical disk 6
There is a method of determining that a light beam is reflected by the flat portion by specifying the flat portion based on the difference in the reflection intensity of the light.

For example, when no diffracted light is generated, the intensity of the reflected light beam becomes larger than when diffracted light is generated. That is, since it is considered that the light beam reflected by the flat portion of the optical disk 6 hardly generates diffracted light, the intensity of the light beam becomes larger than that of the light beam reflected by the land / groove or the pit. Therefore, when the reflection intensity of the light beam becomes larger than a certain reference, it is determined that the light beam is reflected on the flat portion of the optical disk 6, and the spherical aberration may be detected at this time.

In the method of specifying the position of the flat portion as described above and detecting the spherical aberration of the light beam reflected from the specified flat portion, during the recording of information on the optical disk 6 or the reproduction of information from the optical disk 6 Since it can be performed even during the recording and reproduction of information, the spherical aberration can be detected with high sensitivity by the light reflected from the flat portion of the optical disk 6 even during the recording and reproduction of information.

Then, if the spherical aberration is corrected from the detected spherical aberration signal, information can be recorded / reproduced in a better light beam state.

In the optical recording / reproducing apparatus having the above configuration, for example, when the position of the flat portion is specified from the reflection intensity of the light beam, the following operation can be considered. Here, it is the control signal generation circuit 59 that functions as flat portion specifying means for specifying the flat portion of the optical disc 6.

The control signal generation circuit 59 shown in FIG. 1 continues to observe the reflection intensity, and outputs a spherical aberration signal SAES to the second element drive circuit 58 when the reflection intensity becomes a certain value or more. The second element driving circuit 58 controls the driving of the second element actuator 55 so as to correct the spherical aberration generated in the optical system of the optical pickup device 10 based on the input spherical aberration signal SAES.

According to the above-described method, the means for knowing that the light beam is reflected by the mirror portion of the optical disk 6 can be used for an optical disk having a plurality of information recording layers. Spherical aberration detection can be realized in the mirror portion of the recording layer.

Further, even if the diffracted light is generated, the spherical aberration may be detected when the diffracted light does not enter the effective diameter of the objective lens. In this case, the intensity is reduced by the generation of the diffracted light, but the 0th-order light and the 1st-order light do not return to the objective lens because they overlap, so the crosstalk of the tracking error signal TES due to the overlap of the diffracted light with the spherical aberration signal SAES is caused. Aberration signal SAES due to the generation of interference fringes
No decrease in sensitivity.

Further, for example, when the cover glass thickness error is small, the generated spherical aberration is small, so that the spherical aberration is detected and corrected only when reading the optical disk, and the spherical aberration is detected during the information recording / reproducing.・ It is possible to make no correction. In this method, a complicated control system for detecting and correcting spherical aberration during recording and reproduction of information can be omitted.

If the optical disc has a plurality of information recording layers, the spherical aberration is detected and corrected when jumping to each information recording layer. During the recording and reproduction of information, detection and correction of spherical aberration are not performed. The spherical aberration correction amount detected at this time is stored in the storage means, and when jumping again to the information recording layer once read, the spherical aberration correction is performed using the stored spherical aberration correction amount.

As means for correcting spherical aberration from the spherical aberration detected by the above detection method, the first element of the two-element objective lens 9 is used.
Means for correcting by adjusting the interval between the element 4 and the second element 5 can be considered, but is not limited to this. For example, the distance between the semiconductor laser 1 and the collimating lens 3 may be adjusted by moving the collimating lens 3. In this case, the light beam emitted from the semiconductor laser 1 and passing through the collimating lens 3 becomes non-parallel, and spherical aberration can be generated. Then, the spherical aberration of the optical system of the optical pickup device can be corrected by the spherical aberration.

Further, a spherical aberration correcting mechanism may be inserted between the two-element objective lens 9 and the collimating lens 3 as a spherical aberration correcting means. This spherical aberration correction mechanism constitutes an optical system that generates spherical aberration when a light beam passes through the spherical aberration correction mechanism.

As the spherical aberration correcting mechanism, for example, it is conceivable to use an afocal optical system in which a convex lens having a positive power and a concave lens having a negative power are combined. In this case, by adjusting the distance between these two lenses, it is possible to generate a spherical aberration that cancels out the spherical aberration generated in the condensing optical system.

As another configuration of the spherical aberration correcting mechanism, it is conceivable to use an afocal optical system in which two convex lenses having positive power are combined. Also in this case, by adjusting the distance between the two lenses, it is possible to generate a spherical aberration that cancels out the spherical aberration generated in the condensing optical system.

In each of the embodiments, an example in which the present invention is applied to an optical recording / reproducing apparatus has been described. However, the present invention is not limited to this. Also applicable to

Also, the present invention relates to a DVD-ROM device using a DVD-ROM as an optical recording medium, a DVD-RAM device using a DVD-RAM as an optical recording medium, and a CD-ROM using a CD-R / RW as an optical recording medium. The present invention can be applied to an optical recording / reproducing / reproducing apparatus such as an R / RW apparatus, an MD apparatus using an MD as an optical recording medium, and an MO apparatus using an MO as an optical recording medium.

As an optical recording medium, a DVD-ROM or DV
In a D-RAM, a recording layer or a reproduction layer is composed of a plurality of layers. In such a case, the flat portion may be specified for each layer, and the spherical aberration generated in the condensing optical system of the optical pickup device may be detected using the reflected light from the specified flat portion. Therefore, since spherical aberration can be detected with high sensitivity for each layer, information can be recorded / reproduced appropriately.

[0135]

As described above, the aberration detecting method of the present invention irradiates the flat area of the optical recording medium with the light beam having passed through the converging optical system provided in the optical pickup device.
In this configuration, the aberration generated in the light-collecting optical system is detected using the reflected light.

Therefore, it is possible to improve the sensitivity of the aberration detection by detecting the aberration generated in the condensing optical system of the optical pickup device by using the reflected light of the light beam from the flat area of the optical recording medium. It has the effect of being able to do it.

The flat area may be a flat area existing between the reproduction area or the recording area of the optical recording medium.

In this case, in a flat area existing between the reproduction area and the recording area of the optical recording medium, the light beam is reflected in a state where the influence of the area where the grooves, lands or pits are formed is small. Is detected as little as possible, and as a result, there is an effect that aberration can be detected with high sensitivity.

The flat area may be a flat area existing at the innermost or outermost periphery of the optical recording medium.

In this case, the flat area existing at the innermost or outermost area of the optical recording medium is more likely to be a groove, land, or the like than the flat area existing between the reproduction area or the recording area.
Alternatively, since it is formed at a position far from the pit formation region, the influence of diffracted light due to grooves, lands, or pits can be further reduced. As a result, there is an effect that aberration can be detected with higher sensitivity than when reflected light from a flat area existing between a reproduction area and a recording area is used.

Further, the flat area may be specified based on the amount of reflected light of the light beam on the optical recording medium.

In this case, since the flat area of the optical recording medium is specified by the amount of reflected light, it is not necessary to specify the flat area in advance.

If the aberration detection is performed using the reflected light only when the flat area is specified by the amount of reflected light, there is an effect that the aberration can always be detected with high sensitivity.

According to the optical recording / reproducing method of the present invention, as described above, information is recorded / reproduced on / from the optical recording medium using the optical pickup device, and the condensing optical system provided in the optical pickup device is provided. Irradiating the optical recording medium with the light beam that has passed through the optical recording medium, and using the reflected light to detect an aberration generated in the condensing optical system. Identify a flat part existing in the optical recording medium, irradiate the specified flat part with a light beam that has passed through the condensing optical system, and use the reflected light to detect an aberration generated in the condensing optical system. It is the structure which does.

Therefore, the flat portion used for detecting the aberration generated in the condensing optical system is specified, and the aberration generated in the condensing optical system is detected using the reflected light of the light beam from the specified flat portion. Therefore, even when recording and reproducing information on an optical recording medium, without performing complicated control,
There is an effect that aberration generated in the condensing optical system can be easily detected with high sensitivity.

[0146] The flat portion may be specified from a reproduction area of the optical recording medium or an area existing between the recording areas.

In this case, in the flat part specified from the reproduction area of the optical recording medium or the area existing between the recording areas,
Since the light beam is reflected in a state where the influence of the groove, land, or pit formed area is small, the aberration is detected in a state where the influence of the diffracted light is as small as possible,
As a result, there is an effect that aberration can be detected with high sensitivity.

The flat portion may be specified from a region existing at the innermost peripheral portion or the outermost peripheral portion of the optical recording medium.

[0149] In this case, the flat portion specified from the innermost or outermost region of the optical recording medium is more grooved than the flat portion specified from the reproduction region or the region between the recording regions. Since it is formed at a position far from the formation region of the groove, the land, or the pit, the influence of the diffracted light due to the groove, the land, or the pit can be further reduced. As a result, there is an effect that aberration can be detected with higher sensitivity than when reflected light from a flat area existing between a reproduction area and a recording area is used.

The flat portion may be specified based on the intensity of light reflected from the optical recording medium.

In this case, an existing device such as an optical pickup device may be used to obtain the intensity of the reflected light, so that there is no need to provide a special mechanism for specifying the flat portion. This has an effect that a flat portion can be specified at the time of recording and reproducing information on the optical recording medium with a simple configuration.

The position information of the flat portion existing on the optical recording medium may be recorded in the header area where the reproduction or recording position information of the optical recording medium is recorded.

In this case, when recording / reproducing information on / from the optical recording medium, the position information of the flat portion existing on the optical recording medium is recorded in the header area which is always read, so that A flat portion can be reliably specified at the time of recording and reproducing information.

As a result, there is an effect that the aberration occurring in the light collecting optical system can be detected with high sensitivity at the time of recording / reproducing information on / from the optical recording medium.

In the case where the optical recording medium has a plurality of recording layers or reproduction layers, the detection of the aberration generated in the condensing optical system may be performed for each recording layer or each reproduction layer. .

In this case, for each recording layer or each reproduction layer,
Aberration detection can be performed with high sensitivity. Therefore, for example, even when an optical recording medium having a plurality of recording layers or reproduction layers, such as a DVD-RAM or a DVD-ROM, is used, the effect that the aberration can be detected with high sensitivity can be obtained.

As described above, the optical recording / reproducing apparatus of the present invention comprises an optical pickup apparatus for optically recording / reproducing information on / from an optical recording medium and a condensing optical system provided in the optical pickup apparatus. An aberration detecting means for irradiating the optical recording medium with the passed light beam and detecting an aberration generated in the condensing optical system using the reflected light, and a flat surface for specifying a flat portion existing in the optical recording medium. And an aberration detecting means for detecting the aberration based on the reflected light from the flat part specified by the flat part specifying means.

According to the above arrangement, at the time of recording / reproducing information on / from the optical recording medium, the aberration detecting means reflects the reflected light from the flat part existing on the optical recording medium, which is specified by the flat part specifying means. Due to the reflected light, which is less affected by diffracted light,
There is an effect that aberration can be detected with high sensitivity.

The flat portion specifying means may specify a flat portion from a reproduction region of an optical recording medium or a region existing between recording regions.

In this case, in the flat part specified from the reproduction area of the optical recording medium or the area existing between the recording areas,
Since the light beam is reflected in a state where the influence of the groove, land, or pit formed area is small, the aberration is detected in a state where the influence of the diffracted light is as small as possible,
As a result, there is an effect that aberration can be detected with high sensitivity.

The flat portion specifying means may specify a flat portion from an innermost or outermost region of the optical recording medium.

In this case, the flat part specified from the innermost peripheral part or the outermost peripheral part of the optical recording medium is larger than the flat part specified from the area existing between the reproduction area and the recording area.
Since it is formed at a position far from the groove, land, or pit formation region, the influence of diffracted light due to the groove, land, or pit can be further reduced. As a result, there is an effect that aberration can be detected with higher sensitivity than when reflected light from a flat area existing between a reproduction area and a recording area is used.

The flat portion specifying means may specify the flat portion based on the intensity of light reflected from the optical recording medium.

In this case, there is an effect that the flat portion can be specified at the time of recording / reproducing information on the optical recording medium without providing a special mechanism for specifying the flat portion.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram of an optical recording / reproducing apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram of an optical pickup device provided in the optical recording / reproducing apparatus shown in FIG.

FIG. 3 is a schematic configuration diagram of a detection device provided in the optical recording / reproducing device shown in FIG.

FIG. 4 is a graph showing a change in a spherical aberration signal due to a light beam reflected on a flat portion of an optical disc and a light beam reflected on a land / groove of the optical disc.

FIG. 5 is a diagram illustrating an example of a mirror unit existing in a recording area of an optical disc.

FIG. 6 is an explanatory diagram showing a state in which a light beam reflected by a land or groove of an optical disc generates diffracted light.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Semiconductor laser 2 Hologram 2a 1st area 2b 2nd area 3 Collimating lens 4 Lens 1st element (objective lens) 5 Lens 2nd element (objective lens) 6 Optical disk (optical recording medium) 7 Detection device (Aberration detection means 8) detecting device (aberration detecting means) 9 two-element objective lens (condensing optical system) 10 optical pickup device 59 control signal generating circuit (flat portion specifying means) CL1 first straight line CL2 second straight line E1 first circle E2 Second arc OZ Optical axis

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2G086 HH06 5D118 AA13 AA18 BA01 BB08 BC01 CD02 DC03 5D119 AA11 AA22 BA01 EA10 JA44 PA02

Claims (14)

[Claims] A light beam having passed through a converging optical system provided in an optical pickup device is radiated to a flat area of an optical recording medium, and the reflected light is used to detect an aberration generated in the converging optical system. An aberration detecting method. 2. The aberration detecting method according to claim 1, wherein said flat area is a flat area existing between a reproduction area and a recording area of an optical recording medium. 3. The aberration detecting method according to claim 1, wherein the flat area is a flat area existing at an innermost peripheral portion or an outermost peripheral portion of the optical recording medium. 4. The aberration detection device according to claim 1, wherein the flat area is an area specified based on the amount of light reflected by the optical recording medium. Method. 5. An optical recording medium for recording and reproducing information using an optical pickup device, and irradiating the optical recording medium with a light beam passing through a condensing optical system provided in the optical pickup device. Then, in the optical recording and reproducing method for detecting the aberration generated in the condensing optical system using the reflected light, at the time of recording and reproducing information on the optical recording medium, to identify a flat portion present in the optical recording medium, An optical recording / reproducing method comprising: irradiating the specified flat portion with a light beam that has passed through the condensing optical system, and detecting the aberration generated in the condensing optical system using the reflected light. 6. The optical recording / reproducing method according to claim 5, wherein the flat portion is specified from a reproducing region of the optical recording medium or a flat region existing between the recording regions. 7. The optical recording / reproducing method according to claim 5, wherein the flat portion is specified from a flat region existing at an innermost peripheral portion or an outermost peripheral portion of the optical recording medium. 8. The flat portion is specified based on the intensity of light reflected from an optical recording medium.
The optical recording / reproducing method according to any one of the above. 9. The optical disk according to claim 5, wherein position information of a flat portion existing in said optical recording medium is recorded in a header area where information on reproduction or recording position of said optical recording medium is recorded. The optical recording / reproducing method according to any one of the above. 10. When the optical recording medium has a plurality of recording layers or reproduction layers, the detection of aberrations occurring in the condensing optical system is performed for each recording layer or each reproduction layer. The optical recording / reproducing method according to any one of claims 5 to 9. 11. An optical pickup device for optically recording and reproducing information on and from an optical recording medium, and irradiating the optical recording medium with a light beam passing through a converging optical system provided in the optical pickup device. And an aberration detecting means for detecting an aberration generated in the condensing optical system using the reflected light; and a flat part specifying means for specifying a flat part existing in the optical recording medium, wherein the aberration detecting means An optical recording / reproducing apparatus for detecting aberration based on reflected light from a flat portion specified by the flat portion specifying means. 12. The optical recording / reproducing apparatus according to claim 11, wherein said flat portion specifying means specifies a flat portion from a reproduction area of an optical recording medium or an area existing between recording areas. 13. The optical recording / reproducing apparatus according to claim 11, wherein said flat portion specifying means specifies a flat portion from an innermost portion or an outermost portion of the optical recording medium. 14. An optical recording / reproducing apparatus according to claim 11, wherein said flat portion specifying means specifies a flat portion based on the intensity of light reflected from an optical recording medium.